2008
DOI: 10.1098/rspa.2008.0281
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A continuum description of nonlinear elasticity, slip and twinning, with application to sapphire

Abstract: A model is developed for elasticity, plasticity and twinning in anisotropic single crystals subjected to large deformations. Dislocation glide and deformation twinning are dissipative, while energy storage mechanisms associated with dislocation lines and twin boundaries are described via scalar internal state variables. Concepts from continuum crystal plasticity are invoked, with shearing rates on discrete glide and twinning systems modelled explicitly. The model describes aspects of thermomechanical behaviour… Show more

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Cited by 93 publications
(43 citation statements)
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“…Excellent agreement between model predictions and experiment is evident. Post-yielding, shock stress is higher for the case when inelastic density change is included (k > 0), in agreement with predictions for other solids [45]. Stress P is largest for the isentrope since inelastic deformation by slip that would otherwise relieve elastic strain is excluded.…”
Section: Results: Shock Loading Of Magnesiumsupporting
confidence: 73%
“…Excellent agreement between model predictions and experiment is evident. Post-yielding, shock stress is higher for the case when inelastic density change is included (k > 0), in agreement with predictions for other solids [45]. Stress P is largest for the isentrope since inelastic deformation by slip that would otherwise relieve elastic strain is excluded.…”
Section: Results: Shock Loading Of Magnesiumsupporting
confidence: 73%
“…The theory presented here does not address plastic slip, i.e., glide of full and/or partial dislocation lines and loops not associated with twinning. Additional model features are required to simultaneously address plastic slip and twinning [16,36].…”
Section: Kinematicsmentioning
confidence: 99%
“…More generally, the interfacial energy of a growing or shrinking twin also includes elastic and core energies of twinning dislocations comprising such interfaces [9,13,14]. Continuum mechanics models for deformation twinning have been developed in the context of crystal plasticity theory [15,16], wherein at each continuum material point, the volume/mass fraction of a particular twin system is evolved via a kinetic relation usually involving a resolved shear stress criterion. Intended goals of such models include predictions of macroscopic stress-strain behavior and crystallographic texture.…”
Section: Introductionmentioning
confidence: 99%
“…Cohesive zone representations of interfacial separation [23][24][25] offer the potential for more realistic modeling of interfacial physics than the fully bonded or free surface interactions prescribed herein among layers. Constitutive models with a more rigorous basis in finite deformation kinematics [26] and thermodynamics [21] may enable improvements in descriptions of the bulk behavior of metals [23,27] and ceramics [28], albeit at increased model complexity and computational expense. Phase field models [29] of structural transformations (e.g., for high-pressure phase transitions [17] and fracture in AlN) and nonlocal models for inelasticity and damage mechanisms [30] may also offer improvement over usual continuum mechanical treatments available in simulation codes such as EPIC, for example, potential benefits with regard to regularization of numerical solutions.…”
Section: Analysis and Discussionmentioning
confidence: 99%